Method and apparatus for regeneration, recovery and rejuvenation, of cells applying a low frequency electromagnetic pulse which is varied based on environment and/or body conditions

ABSTRACT

An apparatus and method is provided for healing and regeneration of live human and animal bodies and influencing interaction and intercommunication at the cellular level. The apparatus can include one or more environmental and/or body sensors. An electrical circuit can also be provided to produce a square or trapezoidal wave that is delivered to a transducer for application, preferably timed at specific frequencies Delta, Theta, Alpha, to Beta, based on information received from the one or more sensors. In certain embodiments, a DC power source can be provided which allows the apparatus to be portable. A wireless communication module can also be provided.

This application is a Continuation-In-Part of U.S. application Ser. No.14/550,176, filed Nov. 21, 2014, which is a Continuation-In-Part of U.S.application Ser. No. 13/957,979, filed Oct. 2, 2013, which claimspriority to and the benefit of U.S. Application Ser. No. 61/766,226,filed Feb. 19, 2013. All applications are incorporated by reference intheir entireties.

BACKGROUND OF THE DISCLOSURE

Magnetic influence on living bodies has been known for a long timestarting from ancient Greece and Egypt and is currently used as atherapeutic technique in different ways, including with permanentmagnets to pulse an electromagnetic field. Research into magnetictherapy proves the health benefits in living bodies. As a result thenumber of people who sleep on magnetic beds and/or who wear magnetsduring the day is continually increasing. These uses have shown theenergy increase on bodies and have achieved success in the healingprocess.

It turns out that pulse magnetic frequencies appear to act as a wholebody battery recharger by pumping and priming the cells of the body. Thecells in the body are similar to little wet batteries that operateideally at around 70 millivolts. The membrane acts like a one-wayrectifier that converts the earth's magnetic pulse intro electricalpotential energy, which charges the body cells. This energy drives cellmetabolism and enhances oxygenation, improves absorption of nutritionand essential elements into the cell and can help to remove waste out ofthe cell. The entire process of regeneration and healing has usedfrequencies and energy of the planet Earth, namely the Schumann resonantfrequencies and the Earth's magnetic field.

SUMMARY OF THE DISCLOSURE

Disclosed is an apparatus for enhancing regenerative, recovery andhealing of a living body. The disclosed embodiments preferably compriseat least one environmental and/or body sensor connected to an electricalcircuit, which applies a preferred, but not limiting, trapezoidal orsquare wave varying electrical current to a transducer at a differentfrequency to generate an electromagnetic field output.

The disclosed apparatus preferably changes the frequency from Delta,Theta, Alpha to Beta (1 Hz-30 Hz) based on the sensor(s) and willproduce an electromagnetic force intensity of about 0.001 to about 0.45Gauss, continuously forever how long the supplied power is present. Thedisclosed apparatus preferably can generate a same or highly similartype of energy that exist and is created by planet earth.

Thus, the disclosed embodiments provide for a method and apparatus forregenerative, recovery and healing for live humans and animals byapplying a low frequency of an electromagnetic pulse which can be variedbased on one or more environmental and/or body conditions and whichinfluence interaction and intercommunication at the cellular level forbiological organisms and molecular level of matter.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of the main components for one embodiment ofthe energy generating apparatus in accordance with the disclosure;

FIG. 2 is an illustration showing one embodiment for the frequencyresonator that can be used in accordance with the disclosure;

FIG. 3 is an electrical schematic for one embodiment of the disclosedapparatus which is shown using an IC chip and at least one environmentalsensor;

FIG. 4 is an electrical schematic for another embodiment of thedisclosure which includes environmental and bodies sensors incommunication with a microcontroller and the microcontroller incommunication with preferably four coils, though the number of coils isnot considered limiting;

FIG. 5 is an electrical schematic for a further embodiment of thedisclosed apparatus using an IC chip and at least one environmentalsensor with square wave alternative DC;

FIG. 6 is an electrical schematic for still another embodiment of thedisclosed apparatus preferably using at least one environmental sensorin communication with the an IC microcontroller chip, with the outputsignal from the microcontroller a gate T1 to allow the coil to beenergized by a high voltage AC circuit and generating a magnetic pulsefield;

FIG. 7 is an electrical schematic of yet another embodiment of thedisclosed apparatus;

FIG. 8 is an electrical schematic of even still another embodiment ofthe disclosed apparatus;

FIG. 9 is an electrical schematic of still further another embodiment ofthe disclosed apparatus;

FIG. 10, FIG. 11 and FIG. 12 are flowcharts for the memoryconfiguration, data memory and memory program for the disclosedapparatus;

FIG. 13 is an electric schematic for another embodiment of the disclosedapparatus, which can be powered by a DC source of energy (one or morebatteries or rechargeable batteries) in accordance with the presentdisclosure;

FIG. 14 is an electrical schematic of yet another embodiment of thedisclosed apparatus preferably using battery power;

FIG. 15 is an electric schematic for still another embodiment of thedisclosed apparatus preferably using a DC source of energy; and

FIG. 16 illustrate an electric schematic for another embodiment of thedisclosed apparatus preferably provided with wireless communicationcapabilities.

DETAILED DESCRIPTION

The several embodiments for the disclosed apparatus will be more fullydescribed below, but is not limited by the attached figures and ensuingdescription in which:

In FIG. 1 blocks 1A and 1B represent the one or more sensors that can beused with the disclosed apparatus, with Block 1A used to denote one ormore environmental sensor(s), such as, but not limited to, barometricpressure sensor, temperature sensor, oxygen level sensor, photo sensor,etc. One or more multiple sensors or embodied sensor (such as a MPL115A2sensor, though not limiting, which in one miniature foot print can readthe barometric pressure and temperature) can be used in the apparatusfor supplying information which will be used to vary the frequencyand/or electromagnetic intensity. Block 1B shows the one or more sensorsthat can be attached to or located approximate to or near a live bodyand can read, without limitation, body temperature, heartbeat, pH level,etc.

One or multiple environmental sensors (1A) and/or body sensors (1B) canbe in communication with an electrical circuit which is preferably runby a microcontroller or regular integrated circuit (“IC”) (block 2). Thecircuit/microcontroller/IC determines what change to the frequencyand/or electromagnetic field intensity has occurred, if any, based oninformation received from environmental sensor(s) la and/or bodysensor(s) 1 b.

In a more complex embodiment for the apparatus a variety of sensors canbe used for providing the information that is used for determining anyvarying of the frequency and/or the intensity of electromagnetic force.The determination can be based on a programmed algorithm, which willyield the most efficient results for regenerating, balances and healingof a live body. The power (block 4) can be a portable unit withbattery(ies) having between about 6 to about 12 volts, and/or astationary unit using an AC/DC power supply (about 100 to about 240volt; about 50 Hz to about 60 Hz, to about 6 VDC to about 12 VDC). Block3 represents the transducer coil which can be used for supplyingconductive coil (based on the output from the microcontroller or IC)which preferably can be in a square or trapezoidal wave form, thoughsuch is not considered limiting. The transducer or resonator 3 receivesthe electric pulse or signal from the electrical circuit 2 and providesor creates a magnetic pulse output. Based on information received fromsensors 1A and/or 1B the frequency generated by the electrical circuitcan be varied and/or changes can be made to the intensity of themagnetic pulse output from transducer or resonator 3.

Alternatively, the electromagnetic force can be generated by a four axisresonate frequency member preferably composed of four conductive coilsplaced on each side of a trunk pyramid at approximately ⅔ from the basewith both bases being open such that a hand or leg can go through. Inanother embodiment, the coil sizes can be chosen such that they canencompass an entire live human or animal body. The frequency resonatorembodiment shown in FIG. 2 can create a resonant frequency that canprovide increased healing and regeneration of live human and animalbodies.

The frequency resonator shown FIG. 2 can be an electromagnetic resonantassembly preferably compose of four conductive coils connectedsequentially to the microcontroller output two sequentially in oppositeaxis in the same time or all four simultaneous. Other number ofconductive coils can also be provided and similarly connected with themicrocontroller and are also considered within the scope of theinvention.

As seen in FIG. 3, one embodiment for an electrical circuit of theapparatus is disclosed for healing and regenerating live human andanimal bodies and reveals a first novel example for producing anelectromagnetic pulse with a varying frequency, the intensity of themagnetic force and alternating the polarity based on informationreceived from a photo sensor. Though a photo sensor has been shown forthe electrical circuit, it should be recognized that other sensors, suchas, but not limited to, one or more of the above mentioned sensors canalso be selected in place or in addition to the photo sensor, and use ofsuch other sensors are also considered within the scope of thedisclosure.

In this embodiment, in the presence of light a live body usually is inan active stage (awake stage) and the photo sensor can activatetransistor T1 causing resistor R3 to be connected in parallel withresistor R1. With transistor T1 activated, the IC circuit generates afrequency in a high alpha-low beta range (about 11 Hz-about 12.5 Hz). Inthe absence of light or a low intensity of light the living body isusually in a relaxed stage and the photo sensor will not activate thebase of transistor T1. Thus, resistor R3 will not be connected toanything and the IC circuit generates a different frequency of a hightheta-low alpha range (about 7.7 Hz-about 8.2 Hz).

The IC circuit can be setup and/or programmed to generate two differentfrequencies which can alternate at a specific time in order to allow thechanging of polarity of the electromagnetic field. Each frequency can bechanged by information received from any sensor connected to the ICcircuit. The above teaching is not considered limiting and is only onenon-limiting example for functionality of the disclosed apparatuses andone non-limiting use/method for the regenerative, healing apparatus.Similarly, the above presentation for the operation of the circuit shownin FIG. 3 is also applicable when other types of sensor(s) are connectedto the electric circuit.

FIG. 4 shows another embodiment for the apparatus for regenerating andhealing live human and animal bodies by varying the low frequency andintensity of an electromagnetic field in accordance with environmentaland body conditions using an algorithm programmed and stored and runningthru a microcontroller.

FIG. 5 discloses an electrical diagram which produces an alternating DCsquare wave for its output. Generally, resistors R1 and R2 and capacitorC1 in conjunction with IC chip generate a base frequency. In oneembodiment, the IC chip can function as an oscillation circuit. ResistorR3 and transistor T1 can be provided to change, vary or switch the basefrequency up or down and also to change the duty cycle which increasesor decreases the power of the output accordingly. Resistor R4 can beprovided to energize the base of transistors T2 or T3. Transistors T2and T3 can be provided to amplify the signal received from the IC chipand create differentiation of the DC pulse output, and also determinethe polarity of the magnetic field. Other electrical or electroniccomponents that will perform the same functions can be used in replaceof any of the above or below described electrical or electroniccomponents. Similar positioned electrical or electronic components shownor described for other embodiments of the apparatus function similar tothe functions described in FIG. 5.

FIG. 6 discloses an electrical schematic showing one or moreenvironmental sensors that can be used to control and determine thecycles for producing magnetic energy, in connection with any type of120/240 AC outlet. The circuit can be a low voltage AC to DC circuit,which can be made with discrete components or by integrating a AC to DCconverter, providing for an output for about 5 V DC for the ICoscillator or microcontroller. The output of the IC or microcontrollerwill generate train square pulses determined by the environmentalsensors. The square pulses can be applied to the gate of TRIAC (T1).Based on the environmental sensors, the signal cycles sent to the gateof TRIAC T1 allows the high voltage to pass through the transducerproducing the pulsed magnetic energy and allows the alternating current(with a frequency preferably between about 47 to about 65 Hz) to passthrough the transducer at a preferred frequency of about 7 to about 30Hz as dictated by the sensors.

FIG. 7 shows a general basic interconnection of environmental and bodysensor connected to a microcontroller (non-limiting ex.PIC 12F629). Theoutput of the microcontroller opens the gate of TRIAC T1, producingmagnetic force in connection with any 120/240 V ac.

In FIG. 8 the magnetic pulse generator uses a microcontroller having aclock frequency set by an external RC. The output frequency can beadjusted by resistor R1. Resistor R1 can be connected in parallel withone or more resistors (R3, R4, and R5) based on the state of theassociated sensors. The pulses generated can be equal in length and canopen TRIAC T1 allowing the coil to be energized by the AC voltage.

In FIG. 9 environmental and body sensor's sensitivity can be adjusted byprogramming a comparator threshold level in the controller software.Each sensor can produce an electric signal in response to a designatedenvironmental or body purpose (ex. temperature, humidity, heartbeat, pH.etc.). Transistors T2, T3, T4 can be provided to amplify the signals andallows adjustments of the circuit sensitivity by altering the biosvoltage of transistors (T2, T3, T4). A short electric pulse from theoutput of the microcontroller can be sufficient to open the gate of T1and energize the coil through the alternating voltage.

FIG. 10, FIG. 11 and FIG. 12 illustrate the steps and decisionsperformed in connection with the memory configuration; data memory andmemory program, respectively, for the apparatus.

The disclosed apparatus can provide for a magnetic pulse generator, withlow frequency using an IC chip or controller to open a gate, whoseopening allows high voltage (AC) to energize the transducer (coil) forspecific period of time. Preferably, the frequency can be programmed torange anywhere from about 1 Hz to about 170 Hz, though such range is notconsidered limiting.

In summary, the disclosure provides for a method and apparatus forregenerating and healing a live human or animal body. The apparatus canbe comprised of at least one sensor (environmental sensor and/or bodysensor); an electrical circuit generating ultra-low frequency DC waveswith varying (about 1 to about 30 Hz) based on information received fromthe sensor(s), and a transducer or electromagnetic resonator creating anelectromagnetic force based on the output of the electrical circuit, byopening the gate of a TRIAC, semiconductor device or other electronicdevice at ultra-low frequency, allowing low frequency AC current toenergize the transducer and thus providing for a novel and effective wayto rejuvenate (regenerate, heal, balance) live human and animal bodies.The above described apparatus and method can preferably also becomprised with at least one varying component influenced by theinformation received from the sensor(s); and can produce a low frequencyfrom about 1 Hz to about 30 Hz, preferably provided in a square waveform and can have an electromagnetic force intensity from about 0.001Gauss to about 0.45 Gauss.

Preferably, the gate (from a TRIAC, other semiconductor device or otherelectronic device with the equivalent of a gate) can be opened/enabledat an ultra-low frequency provided by the electrical circuit varying thefrequency and the duty cycles. With the gate enabled, on the positiveside of the duty cycles (which can vary with the frequency based oninformation from the sensor(s) the transducer can be energized withsinusoidal wave, low frequency AC current from an AC power supply.

The transducer can be energized with short AC sinusoidal waves lowfrequency (preferably about 47 to about 65 Hz) current (which preferablynever start and stop at same phase or point) only on the positive sideof duty cycles generated by the ultra-low frequency from the electriccircuit, varying the ultra-low frequency, and duty cycle based oninformation from at least one environmental and/or body sensor. In orderto closely replicate earth's magnetic pulse, the AC sinusoidal waveforms preferably do not all start and stop at the same phase or pointsuch that there is no repeating pattern for the starting and stoppingphase point.

The body and environmental sensors could be an integral of the deviceand function as describe above, or the sensors can be separate from thedevice and communicate with the device using known and future developedwireless communication protocols without changing the functionalitydescribed.

In the wireless configuration, the sensors can be a separate modulewhich communicates wirelessly with the main device. Alternatively, thesensors can be existing sensors, such as those provided using an app onan electronic device, such as, but not limited to, a smart phone, cellphone or tablet. In either wireless embodiment, the sensors cancommunicate with the main device in order to change the variables asdescribe above. Non-limiting examples of sensor information that can beobtained using software apps for an electronic device include, but arenot limited to, heartbeat, body temperature, blood sugar level, etc. Theinformation obtained can be wirelessly sent to the main device and havesame functionality and results, benefits, etc. similar to the sensorsthat are provided as an integral part of the device.

The above described parts can be provided within a housing. Where thesensors are integral, the at least one environmental and/or body sensor,the TRIAC (or other semiconductor or electrical device), the electricalcircuit and the transducer or electromagnetic resonator can be containedwithin the housing. In the above described wireless configuration, thesensors would not be contained within the housing. Additionally, anelectrical plug having at least two prongs can extend out of thehousing, with the plug connecting the apparatus with a source of highvoltage AC when the at least two prongs are inserted within a liveelectrical socket outlet.

FIG. 13 illustrates another embodiment this time where a power sourcecan be provided such as one or more batteries or rechargeable batteriesin lieu plugging the apparatus into an AC outlet to allow the apparatusto be mobile. The apparatus shown in FIG. 13 preferably uses at leastone environmental sensor and at least one body sensor to provideinformation to the microcontroller. The microcontroller sends an outputsignal to open a gate T1 to allow a coil to be energized by AC voltagecircuit, preferably created by a DC/AC inverter, to generate a magneticpulse field.

FIG. 15 illustrates another embodiment again where a power source can beprovided such as one or more batteries or rechargeable batteries, oranother DC power source. The apparatus preferably uses at least oneenvironmental sensor which provides information to the microcontroller.The microcontroller or IC sends an output signal to open the gate T1which allows the coil to be energized by AC voltage circuit created bythe DC/AC inverter, to generate a magnetic pulse field.

The apparatus disclosed in FIG. 15 preferably presents one or moreenvironmental sensors that provides the information that can be used tocontrol and determine the cycles for producing magnetic energy, inconnection with alternative current created by the provided DC/ACinverter, using a DC source of power.

As seen in the schematic of FIG. 15, a circuit DC/AC inverter providesthe alternative current output for energizing the resonator. The outputof the IC or microcontroller can generate a train of square wave pulsesdetermined by the information it receives from the environmental sensorsand the signal/output from the IC or microcontroller can be preferablyprovided or applied to the gate of T1 (transistor or triac). Based onthe information received from the environmental sensors, the signalcycles sent to the gate of T1 allow for alternate or alternative (AC)voltage to transfer or pass through the transducer to produce the pulsedmagnetic energy.

The embodiments shown and described in FIG. 13, FIG. 14 and FIG. 15 canpreferably use DC power, which allows the apparatus to be a portableembodiment. The batteries voltage can be in 4.5 to 12 volts range, butsuch range and voltage values are not considered limiting.

The output from the DC/AC inverter does not necessary need to be a highvoltage AC, just AC voltage, of any level (low, mid or high) can beused. Though not considered limiting, the AC output can be in 4 to 220VAC range with a frequency preferably between about 47 to about 150 Hz.All values are provided as examples and are not considered limiting.

Additionally, the disclose apparatus (various embodiments) can be usedwith an electronic device, such as, but not limited to, an APPLE watchor FITBIT technology, to monitor a person's vitals, such as byannouncing when your body needs to be in the proximity of disclosedapparatus (based on range proximity) or to signal or instruct thedisclosed apparatus to increase/decrease frequency. Monitoring vitalscan increase body efficiency and may reduce overall pain.

FIG. 16 illustrates another embodiment of the disclosure which can addor provide a communication module preferably using Wi-Fi data, Bluetoothor cellphone data to communicate with a cellphone, tablet, pc or anyportable device with an operating system (OS system) preferably used tovary frequency and/or intensity of magnetic field based on the bodyvitals information received from the sensors. In this embodiment, theapparatus preferably can have or be provided with a communication moduleusing Wi-Fi data, Bluetooth or cellphone data to communicate with acellphone, tablet, pc or any portable device with an OS system, forvarying frequency or intensity of magnetic field based on body vitalssensors.

The body and environmental sensors can be integral of or internal withinthe device and function as describe above, or the sensors can beseparate from the device and communicate with the device using known andfuture developed wireless communication protocols without changing thefunctionality described.

The apparatus disclosed in FIG. 16 can be provided with a communicationmodule using Wi-Fi data, Bluetooth or cellphone data to communicate witha cellphone, tablet, pc or any portable electronic device with an OSsystem, for varying frequency or intensity of magnetic field based onbody vitals sensors, and all are considered within the scope of thedisclosure.

In the wireless configurations, the sensors can be a separate modulewhich communicates wirelessly with the main device. Alternatively, thesensors can be existing sensors, such as those provided using an App onan electronic device, such as, but not limited to, a smart phone, cellphone, tablet or similar electronic devices. In the wirelessembodiments, the sensors can communicate with the main device in orderto change the variables as describe above. Examples of sensorinformation that can be obtained using one or more software apps for anelectronic device include, but are not limited to, heartbeat, bodytemperature, blood sugar level, pulse rate, blood pressure, etc. Theinformation obtained can be wirelessly sent to the main device and canhave the same functionality and results, benefits, etc. similar to thesensors that are provided as an integral part of the device.

In all embodiments, the apparatus can preferably automatically andcontinuously, on its own, vary simultaneously both the electromagneticenergy and the frequence and can alternative the polarity based onenvironmental information the IC/microcontroller receives from the oneor more environmental sensors and/or based on body/body vitalinformation the IC/microcontroller receives from the one or more bodysensors.

For the non-portable/non-mobile embodiments, when the device/apparatusis connected to an AC outlet it can be “on” and working continuously,and the device does not need to have an on/off switch for turning thedevice off/on, though it is within the scope of the disclosure toinclude such switch to the circuit. Thus, the device can be preferablycontinuously on and thus continuously and automatically feedinginformation from the sensor(s) to the microcontroller. Upon receivinginformation from the sensor(s), a microcontroller preferablyautomatically processes the information and changes and automaticallymakes any adjustments needed on its own and without any input by a humanuser. Thus, for the AC/non-portable embodiments the device canautomatically and continuously vary the frequency, magnetic polarity andintensity on its own.

All measurements, amounts, frequencies, voltages, intensity amounts,sizes, shapes, percentages, configurations, securement or attachmentmechanisms, dimensions, sealing members, numbers, ranges, partlocations, values, percentages, materials, orientations, methods ofmanufacture, etc. discussed above or shown in the drawing figures aremerely by way of example and are not considered limiting and othermeasurements, amounts, frequencies, voltages, intensity amounts, sizes,shapes, percentages, configurations, securement or attachmentmechanisms, dimensions, sealing members, numbers, ranges, partlocations, values, percentages, materials, orientations, methods ofmanufacture, etc. can be chosen and used and all are considered withinthe scope of the disclosure. Additionally, the function of the DC/ACinverter or AC/DC inverter can also be accomplished by a DC/AC converteror AC/DC converter.

Furthermore, one or more features, components, characteristics, sensors,etc. discussed for one embodiment of the disclosure can also be usedwith another of the above discussed embodiments of the disclosure.

Though the disclosed apparatus is preferably for use with human andmammals, the apparatus can be modified to account for body conditions ofother types of living creatures, such as, but not limited to, dogs,horses, cats, reptiles, plants and therefore the concepts, methods andapparatuses of the disclosure are also considered to include use withother types of living creatures.

Additionally, for any numerical ranges discussed above, any combinationof numbers within the range can be used to create a smaller size rangefrom the outer limits of the numerical range specified and all suchsmaller ranges are also considered to be within the scope of thedisclosure and also incorporated by reference without particularlylisting each specific numerical values for the smaller ranges.

Unless feature(s), part(s), component(s), characteristic(s) orfunction(s) described in the specification or shown in the drawings fora claim element, claim step or claim term specifically appear in theclaim with the claim element, claim step or claim term, then theinventor does not considered such feature(s), part(s), component(s),characteristic(s) or function(s) to be included for the claim element,claim step or claim term in the claim for examination purposes and whenand if the claim element, claim step or claim term is interpreted orconstrued. Similarly, with respect to any “means for” elements in theclaims, the inventor considers such language to require only the minimalamount of features, components, steps, or parts from the specificationto achieve the function of the “means for” language and not all of thefeatures, components, steps or parts describe in the specification thatare related to the function of the “means for” language.

While the disclosed apparatus and method have been described anddisclosed in certain terms and has disclosed certain embodiments ormodifications, persons skilled in the art who have acquainted themselveswith the disclosure, will appreciate that it is not necessarily limitedby such terms, nor to the specific embodiments and modificationdisclosed herein. Thus, a wide variety of alternatives, suggested by theteachings herein, can be practiced without departing from the spirit ofthe disclosure, and rights to such alternatives are particularlyreserved and considered within the scope of the disclosure.

What is claimed is:
 1. An apparatus for producing a train ofelectromagnetic pulses for varying the electromagnetic intensity andfrequency, and for alternating polarity of the electromagnetic pulsesbased on information received regarding changes to a condition, saidapparatus comprising: at least one sensor: an electrical componenthaving an electrical gate; at least one transducer or electromagneticresonator in electrical connection with a source of AC voltage andcapable of generating the train of electromagnetic pulses; and anelectrical circuit producing an output, said output being ultra-lowfrequency waves having a duty cycle, said electrical circuit inelectrical communication with the at least one sensor, said electricalcircuit including a microcontroller or IC oscillator chip capable ofautomatically varying a frequency and intensity of the electromagneticpulses, the output of the electrical circuit being sent to and enablingthe gate of the electrical components, wherein enabling of the gateoccurs only on a positive side of the duty cycle so as to energize theat least one transducer or electromagnetic resonator with short ACsinusoidal wave forms at low frequency AC current from the source of ACvoltage, wherein the short AC sinusoidal wave forms do not share a samephase or starting point such that there is no repeating pattern for astarting and stopping phase point in order to closely replicate earth'smagnetic pulse; wherein the at least one transducer or electromagneticresonator generates the electromagnetic pulses when the output of theelectrical circuit enables the gate of the electrical component andwherein the output produced by the electrical circuit is based on afrequency dictated by the at least one sensor; wherein a change in thefrequency of the output causes changes in the electromagnetic intensityand frequency and in the polarity of the train of electromagnetic pulsescreated by the at least one transducer or electromagnetic resonator. 2.The apparatus of claim 1 wherein the ultra-low frequency waves of theoutput are automatically and continuously varied based on informationthe microcontroller or IC oscillator chip receives from the at least onesensor.
 3. The apparatus of claim 1 further comprising: a DC voltagepower source; and a DC/AC inverter in electrical communication with theDC voltage power source and the at least one transducer orelectromagnetic resonator; wherein the DC/AC inverter receives a sourceof DC voltage from the DC voltage power source and converts the DCvoltage in the source of AC voltage which is then provided to the atleast one transducer or electromagnetic resonator.
 4. The apparatus ofclaim 3 wherein the DC voltage power source is one or more batteries. 5.The apparatus of claim 4 wherein the apparatus is portable.
 6. Theapparatus of claim 1 wherein the at least one sensor is at least oneenvironmental sensor.
 7. The apparatus of claim 6 wherein said at leastone environmental sensor is a photo, temperature, humidity oratmospheric pressure sensor.
 8. The apparatus of claim 1 wherein the atleast one sensor is at least one body sensor.
 9. The apparatus of claim1 further comprising a wireless communication module in electricalcommunication with the at least one sensor.
 10. The apparatus of claim 1wherein the ultra-low frequency waves of the output of the electricalcircuit are ultra-low frequency square wave pulses, wherein values ofthe square wave pulses are determined by information received from theat least one environmental sensor.
 11. The apparatus of claim 1 whereinwhen the gate of the electrical component is enabled, the low frequencyshort AC sinusoidal wave forms is permitted to pass through the at leastone transducer or electromagnetic resonator to produce the train ofelectromagnetic pulses.
 12. The apparatus of claim 1 wherein said outputis in an AC pulse sinusoidal wave form.
 13. A portable apparatus forproducing a train of electromagnetic pulses for varying theelectromagnetic intensity and frequency, and for alternating polarity ofthe electromagnetic pulses based on information received regardingchanges to a condition, said apparatus comprising: at least one sensor:an electrical component having an electrical gate; at least onetransducer or electromagnetic resonator capable of generating the trainof electromagnetic pulses; a DC voltage power source; and a DC/ACinverter in electrical communication with the DC voltage power sourceand the at least one transducer or electromagnetic resonator; whereinthe DC/AC inverter receives a source of DC voltage from the DC voltagepower source and converts the DC voltage in the source of AC voltagewhich is then provided to the at least one transducer or electromagneticresonator; and an electrical circuit producing an output, said outputbeing ultra-low frequency waves having a duty cycle, said electricalcircuit in electrical communication with the at least one sensor, saidelectrical circuit including a microcontroller or IC oscillator chipcapable of automatically varying a frequency and intensity of theelectromagnetic pulses, the output of the electrical circuit being sentto and enabling the gate of the electrical components, wherein enablingof the gate occurs only on a positive side of the duty cycle so as toenergize the at least one transducer or electromagnetic resonator withshort AC sinusoidal wave forms at low frequency AC current from thesource of AC voltage, wherein the short AC sinusoidal wave forms do notshare a same phase or starting point such that there is no repeatingpattern for a starting and stopping phase point in order to closelyreplicate earth's magnetic pulse; wherein the at least one transducer orelectromagnetic resonator generates the electromagnetic pulses when theoutput of the electrical circuit enables the gate of the electricalcomponent and wherein the output produced by the electrical circuit isbased on a frequency dictated by the at least one sensor; wherein achange in the frequency of the output causes changes in theelectromagnetic intensity and frequency and in the polarity of the trainof electromagnetic pulses created by the at least one transducer orelectromagnetic resonator.
 14. The portable apparatus of claim 13wherein the ultra-low frequency waves of the output are automaticallyand continuously varied based on information the microcontroller or ICoscillator chip receives from the at least one sensor.
 15. The apparatusof claim 13 wherein the at least one sensor is at least oneenvironmental sensor and the condition is a change in at least oneenvironmental condition.
 16. The apparatus of claim 13 wherein the atleast one sensor is at least one body sensor and the condition is achange in at least one body condition.
 17. The apparatus of claim 13wherein the DC voltage power source is one or more batteries.
 18. Theapparatus of claim 13 further comprising a wireless communication modulein electrical communication with the at least one sensor.
 19. A methodfor producing pulsed magnetic energy based on at least one environmentalcondition, said method comprising the steps of: (a) receivinginformation from at least one environmental or body sensor; (b)generating a pulsed DC square wave output by an electrical circuit basedon the information received from the at least one environmental sensor,the electrical circuit including a microcontroller or IC oscillatorchip; (c) producing pulsed magnetic energy by at least one transducer orelectromagnetic resonator based on a frequency of the pulsed DC squarewave output; and (d) automatically varying an intensity of the pulsedmagnetic energy by automatically varying the frequency of the pulsed DCsquare wave output by the electrical circuit based on the informationreceived from the at least one environmental sensor.
 20. The method ofclaim 19 wherein step (c) comprises the steps of enabling a gate of asemiconductor device or electrical component with the pulsed DC squarewave output to allow high voltage low frequency AC in sinusoidal waveform to pass through the at least one transducer or electromagneticresonator.